Aim To discover putative oncogenes in head and neck squamous cell

Aim To discover putative oncogenes in head and neck squamous cell carcinoma (HNSCC) by integrating data from whole-genome comparison of array-based comparative genomic hybridization (CGH) and expression microarray analysis of HNSCC. of 2.1 (SE = 0.35) (p = 0.0008). was found to be amplified and overexpressed in 3 HNSCC cell lines. Knockdown of 3-deazaneplanocin A HCl IC50 in cell lines (JHU-012 and JHU-011) inhibited proliferation. Conclusion is amplified and overexpressed in HNSCC cell lines and primary tumors and functionally significant in cell lines. encodes a protein that is NR4A3 a member of the Argonaute family of proteins. These proteins are known to play a role in RNA interference. MicroRNA are non-coding RNA molecules that were found to regulate gene expression 3-deazaneplanocin A HCl IC50 post-transcriptionally. The encoded protein is a component of the RNA-induced silencing complex (RISC), a key factor in the microRNA, siRNA and RNAi processing pathway [5]. In summary, microRNA are transcribed from DNA into pre-microRNA, these molecules are then processed by Drosha in the nucleus and exported out of the nucleus by Exportin 5. Once exported from the nucleus, the microRNA are further processed by Dicer which produces the mature single-stranded form. Lastly, this mature microRNA associates with RISC and then binds to its target mRNA and inhibits translation by degradation of target mRNA and/or blockage of translation. provides the endonuclease activity (also called slicer) to RISC by cleaving microRNA/mRNA heteroduplexes bound to RISC [5,6]. There have been many studies implicating the role of microRNA in many malignancies by either overexpression or underexpression [7]. To validate the results of our integrative discovery approach, we performed functional studies using in cell lines. After validating overexpression of by RT-PCR in a separate cohort of HNSCC tumors, we demonstrated that can modulate cellular proliferation using siRNA knockout experiments. Since normally functions in the pathway of microRNA, it is possible that alterations in microRNA processing components may contribute toward a malignant phenotype. Methods Human Tissue Samples All human HNSCC tissue samples and normal mucosal tissues were obtained and used according to the policies of the JHMI institutional review board. Tissues were snap frozen in liquid nitrogen immediately after collection. Microdissection of frozen tissue was performed to assure that more than 75% of tissue contained HNSCC. Microdissection was performed by a Johns Hopkins Hospital head and neck pathologist. Eight samples of HNSCC and 6 samples of normal oral epithelial tissue were used for the mRNA expression array (online suppl. table 1, www.karger.com/doi/10.1159/000320597). A separate cohort of 3-deazaneplanocin A HCl IC50 34 microdissected HNSCC tumors and 8 normal oral epithelial tissues was used for the validation studies. All normal tissues were derived from patients who underwent uvulopalatopharyngoplasty for obstructive sleep apnea. DNA and RNA Extraction Total RNA extraction from human tissue samples and cell lines was performed using Trizol reagent (Invitrogen, Carlsbad, Calif., USA). Methods used were as described by Chomczynski [8] and Chomczynski and Sacchi [9]. mRNA Expression Array and Significance Analysis of Microarray RNA was analyzed by human 3-deazaneplanocin A HCl IC50 genome Affymetrix U133 1.0 mRNA expression array chip (Affymetrix, Santa Clara, Calif., USA) which examines the expression of 12,000 genes simultaneously. A logarithmic transformation was then performed using the Snomad software. Final values for each sample, expressed as a Z score, were analyzed for significance using significance analysis of microarray (SAM). SAM was applied to expression array results that examined the 8 samples of primary HNSCC and 3-deazaneplanocin A HCl IC50 6 samples of normal control oral epithelial tissue. For SAM, a q.